Conversion of sucrose to isomaltulose by Klebsiella planticola CCRC 19112

An isomaltulose-producing bacterium was isolated and taxonomically characterized. Its morphological and biochemical properties conform best to those described for Klebsiella planticola. When cultured under optimal conditions, the organism simultaneously converted sucrose into both isomaltulose (α-D-glucopyranosyl-1,6-fructose) and trehalulose (α-D-glucopyranosyl-1,1-fructose) with substrate conversion rates of 80% and 15%, respectively. Sucrose and Bacto-tryptone were the most effective carbon and supplemental nitrogen sources, respectively, for producing cells of high isomaltulose-forming ability. None of several inorganic salts tested had any significant effect. The major product formed in the reaction mixture was verified to be isomaltulose by co-chromatography and IR spectroscopy. Received 21 April 1998/ Accepted in revised form 7 July 1998     

Feeding rates and carbohydrate metabolism by Bemisia tabaci (Homoptera: Aleyrodidae) on different quality phloem saps

Abstract.The effects of water stress on phloem sap quality of the melon, Cucumis melo, and how this, in turn, has an impact on the sweet potato whitefly, Bemisia tabaci were studied. Melon plants were grown under watering regimes that produced plants with or without water stress. Plants showed strong developmental responses to the treatments; water-stressed plants were shorter, with fewer, smaller leaves than those without stress. There was, however, no effect of plant water stress on the development period of whiteflies feeding on these plants, or on the weights of male or female adults. Honeydew production was used as an indirect measure to test whether the absence of insect developmental or behavioural effects was due to differential phloem sap ingestion. Feeding rates on the stressed plants were almost half those on unstressed plants, and there was also variation in the daily pattern of honeydew production. Phloem sap and honeydew were analysed to determine why the feeding behaviours differed. Amino acid composition of the phloem sap was similar in both groups of plants, but carbohydrate concentrations were greater in water-stressed plants, indicating that lower feeding rates may have been due either to the physical or nutritional quality of the phloem sap. The honeydew of insects that were feeding on water-stressed plants contained a greater concentration of carbohydrate than those on unstressed plants, and was composed of a significantly greater proportion of glucose and the disaccharide, trehalulose. This isomerization of more complex sugars from those in the diet suggests that B. tabaci uses a mechanism of osmoregulation to actively maintain its internal water status. It is concluded that transient conditions of water stress in this host plant do not affect the development of B. tabaci, due to physiological and behavioural changes in response to diets with different nutritional and physical properties. The implications of this finding for the feeding biology of B. tabaci on desert-grown crops are discussed.     

Insights into sucrose isomerization from crystal structures of the Pseudomonas mesoacidophila MX-45 sucrose isomerase,MutB

Three-dimensional structures of a sucrose isomerase from Pseudomonas mesoacidophila MX-45, forming mainly trehalulose have been solved to resolutions in the range 1.8–2.2 Å. Native and mutant complexes give, for the first time, a thorough insight into substrate binding and recognition, and product specificities of these enzymes. This study has pinpointed essential residues for binding the substrate sucrose, and hereby given detailed information on the interactions between the enzyme active site and glucosyl- and fructosyl moieties. Moreover, the 3-D structures revealed an aromatic clamp formed by two phenylalanines, which plays an essential role in recognition of the substrate and in controlling the reaction specificity.     

Microbial sucrose isomerases: producing organisms, genes and enzymes

Sucrose isomerase (SI) activity is used industrially for the conversion of sucrose into isomers, particularly isomaltulose or trehalulose, which have properties advantageous over sucrose for some food uses. All of the known microbial SIs are TIM barrel proteins that convert sucrose without need for any cofactors, with varying kinetics and product specificities. The current analysis was undertaken to bridge key gaps between the information in patents and scientific publications about the microbes and enzymes useful for sucrose isomer production.This analysis shows that microbial SIs can be considered in 5 structural classes with corresponding functional distinctions that broadly align with the taxonomic differences between producing organisms. The most widely used bacterial strain for industrial production of isomaltulose, widely referred to as “Protaminobacter rubrum” CBS 574.77, is identified as Serratia plymuthica. The strain producing the most structurally divergent SI, with a high product specificity for trehalulose, widely referred to as “Pseudomonas mesoacidophila” MX-45, is identified as Rhizobium sp.Each tested SI-producer is shown to have a single SI gene and enzyme, so the properties reported previously for the isolated proteins can reasonably be associated with the products of the genes subsequently cloned from the same isolates and SI classes. Some natural isolates with potent SI activity do not catabolize the isomer under usual production conditions. The results indicate that their industrial potential may be further enhanced by selection for variants that do not catabolize the sucrose substrate.     

Characterization of Pantoea dispersa UQ68J: producer of a highly efficient sucrose isomerase for isomaltulose biosynthesis

AIMS: Isolation, identification and characterization of a highly efficient isomaltulose producer. METHODS AND RESULTS: After an enrichment procedure for bacteria likely to metabolize isomaltulose in sucrose-rich environments, 578 isolates were screened for efficient isomaltulose biosynthesis using an aniline/diphenylamine assay and capillary electrophoresis. An isolate designated UQ68J was exceptionally efficient in sucrose isomerase activity. Conversion of sucrose into isomaltulose by UQ68J (enzyme activity of 90-100 U mg(-1) DW) was much faster than the current industrial strain Protaminobacter rubrum CBS574.77 (41-66 U mg(-1) DW) or a reference strain of Erwinia rhapontici (0.3-0.9 U mg(-1) DW). Maximum yield of isomaltulose at 78-80% of supplied sucrose was achieved in less than half the reaction time needed by CBS574.77, and the amount of contaminating trehalulose (4%) was the lowest recorded from an isomaltulose-producing microbe. UQ68J is a Gram negative, facultatively anaerobic, motile, noncapsulate, straight rod-shaped bacterium producing acid but no gas from glucose. Based on 16S rDNA analysis UQ68J is closest to Klebsiella oxytoca, but it differs from Klebsiella in defining characteristics and most closely resembles Pantoea dispersa in phenotype. SIGNIFICANCE AND IMPACT OF STUDY: This organism is likely to have substantial advantage over previously characterized sucrose isomerase producers for the industrial production of isomaltulose.     

大黄欧文氏菌蔗糖异构酶基因克隆表达及其酶学特性研究

通过PCR克隆得到了不包括信号肽序列的109～1803bp大黄欧文氏菌蔗糖异构酶基因,以pQE30为表达载体可以在大肠杆菌中高效表达SI基因,但容易形成包涵体。通过降低诱导剂IPTG至10μmol／L,28℃低温诱导表达可以改进表达产物的可溶性。重组SI的最适pH为6．0,最适反应温度为30℃。测定的Km为46．8mmol／L,Vm甜为152．2u／mg。重组SI对麦芽糖、海藻糖、棉子糖、三氯蔗糖及廿甲基葡萄糖苷等均不起作用,只利用蔗糖为底物转糖苷,也可以水解对硝基苯酚-α-葡萄糖苷。同时发现重组SI具有转化异麦芽酮糖生成海藻酮糖的活性。     

Rapid method for trehalulose production and its purification by preparative high-performance liquid chromatography

Trehalulose was produced with a good yield by enzymatic conversion of sucrose and easily purified by preparative HPLC using a single Ca2+-based column. In addition, the structure of this sugar was confirmed by 13C and 1H n.m.r studies.     

Bacterial sucrose isomerases: properties and structural studies

Due to their significant role in food industry, sucrose isomerases are good candidates for rational protein engineering. Hence, specific modifications in order to modify substrate affinity and selectivity, product specificity but also to adapt their catalytic properties to particular industrial process conditions, is interesting. Our work on the structural studies of the sucrose isomerase, MutB, which presents the first structural data available on a trehalulose synthase and the first experimental data on complexed forms of sucrose isomerases represents a significant advance in the understanding of these enzymes. In this review we give an overview of what is known on biochemical properties and structural aspects of different sucrose isomerases in particular those reported from bacteria.